courgette/courgette_tool.cc - chromium/src - Git at Google

 // Copyright (c) 2011 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include <stdarg.h>
 #include <stddef.h>
 #include <stdint.h>

 #include <initializer_list>
 #include <memory>
 #include <string>
 #include <vector>

 #include "base/at_exit.h"
 #include "base/command_line.h"
 #include "base/files/file_path.h"
 #include "base/files/file_util.h"
 #include "base/files/memory_mapped_file.h"
 #include "base/logging.h"
 #include "base/macros.h"
 #include "base/strings/string_number_conversions.h"
 #include "base/strings/string_util.h"
 #include "base/strings/utf_string_conversions.h"
 #include "courgette/assembly_program.h"
 #include "courgette/courgette.h"
 #include "courgette/courgette_flow.h"
 #include "courgette/encoded_program.h"
 #include "courgette/program_detector.h"
 #include "courgette/streams.h"
 #include "courgette/third_party/bsdiff/bsdiff.h"

 namespace {

 using courgette::CourgetteFlow;

 const char kUsageGen[] = "-gen <old_in> <new_in> <patch_out>";
 const char kUsageApply[] = "-apply <old_in> <patch_in> <new_out>";
 const char kUsageGenbsdiff[] = "-genbsdiff <old_in> <new_in> <patch_out>";
 const char kUsageApplybsdiff[] = "-applybsdiff <old_in> <patch_in> <new_out>";
 const char kUsageSupported[] = "-supported <exec_file_in>";
 const char kUsageDis[] = "-dis <exec_file_in> <assembly_file_out>";
 const char kUsageAsm[] = "-asm <assembly_file_in> <exec_file_out>";
 const char kUsageDisadj[] = "-disadj <old_in> <new_in> <new_assembly_file_out>";
 const char kUsageGen1[] = "-gen1[au] <old_in> <new_in> <patch_base_out>";

 /******** Utilities to print help and exit ********/

 void PrintHelp() {
   fprintf(stderr, "Main Usage:\n");
   for (auto usage :
        {kUsageGen, kUsageApply, kUsageGenbsdiff, kUsageApplybsdiff}) {
     fprintf(stderr, "  courgette %s\n", usage);
   }
   fprintf(stderr, "Diagnosis Usage:\n");
   for (auto usage :
        {kUsageSupported, kUsageDis, kUsageAsm, kUsageDisadj, kUsageGen1}) {
     fprintf(stderr, "  courgette %s\n", usage);
   }
 }

 void UsageProblem(const char* message) {
   fprintf(stderr, "%s", message);
   fprintf(stderr, "\n");
   PrintHelp();
   exit(1);
 }

 void Problem(const char* format, ...) {
   va_list args;
   va_start(args, format);
   vfprintf(stderr, format, args);
   fprintf(stderr, "\n");
   va_end(args);
   exit(1);
 }

 /******** BufferedFileReader ********/

 // A file reader that calls Problem() on failure.
 class BufferedFileReader : public courgette::BasicBuffer {
  public:
   BufferedFileReader(const base::FilePath& file_name, const char* kind) {
     if (!buffer_.Initialize(file_name))
       Problem("Can't read %s file.", kind);
   }
   ~BufferedFileReader() override = default;

   // courgette::BasicBuffer:
   const uint8_t* data() const override { return buffer_.data(); }
   size_t length() const override { return buffer_.length(); }

  private:
   base::MemoryMappedFile buffer_;

   DISALLOW_COPY_AND_ASSIGN(BufferedFileReader);
 };

 /******** Various helpers ********/

 void WriteSinkToFile(const courgette::SinkStream* sink,
                      const base::FilePath& output_file) {
   int count = base::WriteFile(output_file,
                               reinterpret_cast<const char*>(sink->Buffer()),
                               static_cast<int>(sink->Length()));
   if (count == -1)
     Problem("Can't write output.");
   if (static_cast<size_t>(count) != sink->Length())
     Problem("Incomplete write.");
 }

 bool Supported(const base::FilePath& input_file) {
   bool result = false;

   BufferedFileReader buffer(input_file, "input");

   courgette::ExecutableType type;
   size_t detected_length;

   DetectExecutableType(buffer.data(), buffer.length(), &type, &detected_length);

   // If the detection fails, we just fall back on UNKNOWN
   std::string format = "Unsupported";

   switch (type) {
     case courgette::EXE_UNKNOWN:
       break;

     case courgette::EXE_WIN_32_X86:
       format = "Windows 32 PE";
       result = true;
       break;

     case courgette::EXE_ELF_32_X86:
       format = "ELF 32 X86";
       result = true;
       break;

     case courgette::EXE_ELF_32_ARM:
       format = "ELF 32 ARM";
       result = true;
       break;

     case courgette::EXE_WIN_32_X64:
       format = "Windows 64 PE";
       result = true;
       break;
   }

   printf("%s Executable\n", format.c_str());
   return result;
 }

 void Disassemble(const base::FilePath& input_file,
                  const base::FilePath& output_file) {
   CourgetteFlow flow;
   BufferedFileReader input_buffer(input_file, flow.name(flow.ONLY));
   flow.ReadDisassemblerFromBuffer(flow.ONLY, input_buffer);
   flow.CreateAssemblyProgramFromDisassembler(flow.ONLY, false);
   flow.CreateEncodedProgramFromDisassemblerAndAssemblyProgram(flow.ONLY);
   flow.DestroyDisassembler(flow.ONLY);
   flow.DestroyAssemblyProgram(flow.ONLY);
   flow.WriteSinkStreamSetFromEncodedProgram(flow.ONLY);
   flow.DestroyEncodedProgram(flow.ONLY);
   courgette::SinkStream sink;
   flow.WriteSinkStreamFromSinkStreamSet(flow.ONLY, &sink);
   if (flow.failed())
     Problem(flow.message().c_str());

   WriteSinkToFile(&sink, output_file);
 }

 void DisassembleAndAdjust(const base::FilePath& old_file,
                           const base::FilePath& new_file,
                           const base::FilePath& output_file) {
   // Flow graph and process sequence (DA = Disassembler, AP = AssemblyProgram,
   // EP = EncodedProgram, Adj = Adjusted):
   //   [1 Old DA] --> [2 Old AP]    [4 New AP] <-- [3 New DA]
   //                      |             |              |
   //                      |             v (move)       v
   //                      +---> [5 Adj New AP] --> [6 New EP]
   //                                               (7 Write)
   CourgetteFlow flow;
   BufferedFileReader old_buffer(old_file, flow.name(flow.OLD));
   BufferedFileReader new_buffer(new_file, flow.name(flow.NEW));
   flow.ReadDisassemblerFromBuffer(flow.OLD, old_buffer);       // 1
   flow.CreateAssemblyProgramFromDisassembler(flow.OLD, true);  // 2
   flow.DestroyDisassembler(flow.OLD);
   flow.ReadDisassemblerFromBuffer(flow.NEW, new_buffer);       // 3
   flow.CreateAssemblyProgramFromDisassembler(flow.NEW, true);  // 4
   flow.AdjustNewAssemblyProgramToMatchOld();                   // 5
   flow.DestroyAssemblyProgram(flow.OLD);
   flow.CreateEncodedProgramFromDisassemblerAndAssemblyProgram(flow.NEW);  // 6
   flow.DestroyAssemblyProgram(flow.NEW);
   flow.DestroyDisassembler(flow.NEW);
   flow.WriteSinkStreamSetFromEncodedProgram(flow.NEW);  // 7
   flow.DestroyEncodedProgram(flow.NEW);
   courgette::SinkStream sink;
   flow.WriteSinkStreamFromSinkStreamSet(flow.NEW, &sink);
   if (flow.failed())
     Problem(flow.message().c_str());

   WriteSinkToFile(&sink, output_file);
 }

 // Diffs two executable files, write a set of files for the diff, one file per
 // stream of the EncodedProgram format.  Each file is the bsdiff between the
 // original file's stream and the new file's stream.  This is completely
 // uninteresting to users, but it is handy for seeing how much each which
 // streams are contributing to the final file size.  Adjustment is optional.
 void DisassembleAdjustDiff(const base::FilePath& old_file,
                            const base::FilePath& new_file,
                            const base::FilePath& output_file_root,
                            bool adjust) {
   // Same as PatchGeneratorX86_32::Transform(), except Adjust is optional, and
   // |flow|'s internal SinkStreamSet get used.
   // Flow graph and process sequence (DA = Disassembler, AP = AssemblyProgram,
   // EP = EncodedProgram, Adj = Adjusted):
   //   [1 Old DA] --> [2 Old AP]   [6 New AP] <-- [5 New DA]
   //       |            |   |          |              |
   //       v            |   |          v (move)       v
   //   [3 Old EP] <-----+   +->[7 Adj New AP] --> [8 New EP]
   //   (4 Write)                                  (9 Write)
   CourgetteFlow flow;
   BufferedFileReader old_buffer(old_file, flow.name(flow.OLD));
   BufferedFileReader new_buffer(new_file, flow.name(flow.NEW));
   flow.ReadDisassemblerFromBuffer(flow.OLD, old_buffer);                  // 1
   flow.CreateAssemblyProgramFromDisassembler(flow.OLD, adjust);           // 2
   flow.CreateEncodedProgramFromDisassemblerAndAssemblyProgram(flow.OLD);  // 3
   flow.DestroyDisassembler(flow.OLD);
   flow.WriteSinkStreamSetFromEncodedProgram(flow.OLD);  // 4
   flow.DestroyEncodedProgram(flow.OLD);
   flow.ReadDisassemblerFromBuffer(flow.NEW, new_buffer);         // 5
   flow.CreateAssemblyProgramFromDisassembler(flow.NEW, adjust);  // 6
   if (adjust)
     flow.AdjustNewAssemblyProgramToMatchOld();  // 7, optional
   flow.DestroyAssemblyProgram(flow.OLD);
   flow.CreateEncodedProgramFromDisassemblerAndAssemblyProgram(flow.NEW);  // 8
   flow.DestroyAssemblyProgram(flow.NEW);
   flow.DestroyDisassembler(flow.NEW);
   flow.WriteSinkStreamSetFromEncodedProgram(flow.NEW);  // 9
   flow.DestroyEncodedProgram(flow.NEW);
   if (flow.failed())
     Problem(flow.message().c_str());

   courgette::SinkStream empty_sink;
   for (int i = 0;; ++i) {
     courgette::SinkStream* old_stream = flow.data(flow.OLD)->sinks.stream(i);
     courgette::SinkStream* new_stream = flow.data(flow.NEW)->sinks.stream(i);
     if (old_stream == NULL && new_stream == NULL)
       break;

     courgette::SourceStream old_source;
     courgette::SourceStream new_source;
     old_source.Init(old_stream ? *old_stream : empty_sink);
     new_source.Init(new_stream ? *new_stream : empty_sink);
     courgette::SinkStream patch_stream;
     bsdiff::BSDiffStatus status =
         bsdiff::CreateBinaryPatch(&old_source, &new_source, &patch_stream);
     if (status != bsdiff::OK)
       Problem("-xxx failed.");

     std::string append = std::string("-") + base::IntToString(i);

     WriteSinkToFile(&patch_stream,
                     output_file_root.InsertBeforeExtensionASCII(append));
   }
 }

 void Assemble(const base::FilePath& input_file,
               const base::FilePath& output_file) {
   CourgetteFlow flow;
   BufferedFileReader input_buffer(input_file, flow.name(flow.ONLY));
   flow.ReadSourceStreamSetFromBuffer(flow.ONLY, input_buffer);
   flow.ReadEncodedProgramFromSourceStreamSet(flow.ONLY);
   courgette::SinkStream sink;
   flow.WriteExecutableFromEncodedProgram(flow.ONLY, &sink);
   if (flow.failed())
     Problem(flow.message().c_str());

   WriteSinkToFile(&sink, output_file);
 }

 void GenerateEnsemblePatch(const base::FilePath& old_file,
                            const base::FilePath& new_file,
                            const base::FilePath& patch_file) {
   BufferedFileReader old_buffer(old_file, "'old' input");
   BufferedFileReader new_buffer(new_file, "'new' input");

   courgette::SourceStream old_stream;
   courgette::SourceStream new_stream;
   old_stream.Init(old_buffer.data(), old_buffer.length());
   new_stream.Init(new_buffer.data(), new_buffer.length());

   courgette::SinkStream patch_stream;
   courgette::Status status =
       courgette::GenerateEnsemblePatch(&old_stream, &new_stream, &patch_stream);

   if (status != courgette::C_OK)
     Problem("-gen failed.");

   WriteSinkToFile(&patch_stream, patch_file);
 }

 void ApplyEnsemblePatch(const base::FilePath& old_file,
                         const base::FilePath& patch_file,
                         const base::FilePath& new_file) {
   // We do things a little differently here in order to call the same Courgette
   // entry point as the installer.  That entry point point takes file names and
   // returns an status code but does not output any diagnostics.

   courgette::Status status = courgette::ApplyEnsemblePatch(
       old_file.value().c_str(), patch_file.value().c_str(),
       new_file.value().c_str());

   if (status == courgette::C_OK)
     return;

   // Diagnose the error.
   switch (status) {
     case courgette::C_BAD_ENSEMBLE_MAGIC:
       Problem("Not a courgette patch");
       break;

     case courgette::C_BAD_ENSEMBLE_VERSION:
       Problem("Wrong version patch");
       break;

     case courgette::C_BAD_ENSEMBLE_HEADER:
       Problem("Corrupt patch");
       break;

     case courgette::C_DISASSEMBLY_FAILED:
       Problem("Disassembly failed (could be because of memory issues)");
       break;

     case courgette::C_STREAM_ERROR:
       Problem("Stream error (likely out of memory or disk space)");
       break;

     default:
       break;
   }

   // If we failed due to a missing input file, this will print the message.
   { BufferedFileReader old_buffer(old_file, "'old' input"); }
   { BufferedFileReader patch_buffer(patch_file, "'patch' input"); }

   // Non-input related errors:
   if (status == courgette::C_WRITE_OPEN_ERROR)
     Problem("Can't open output");
   if (status == courgette::C_WRITE_ERROR)
     Problem("Can't write output");

   Problem("-apply failed.");
 }

 void GenerateBSDiffPatch(const base::FilePath& old_file,
                          const base::FilePath& new_file,
                          const base::FilePath& patch_file) {
   BufferedFileReader old_buffer(old_file, "'old' input");
   BufferedFileReader new_buffer(new_file, "'new' input");

   courgette::SourceStream old_stream;
   courgette::SourceStream new_stream;
   old_stream.Init(old_buffer.data(), old_buffer.length());
   new_stream.Init(new_buffer.data(), new_buffer.length());

   courgette::SinkStream patch_stream;
   bsdiff::BSDiffStatus status =
       bsdiff::CreateBinaryPatch(&old_stream, &new_stream, &patch_stream);

   if (status != bsdiff::OK)
     Problem("-genbsdiff failed.");

   WriteSinkToFile(&patch_stream, patch_file);
 }

 void ApplyBSDiffPatch(const base::FilePath& old_file,
                       const base::FilePath& patch_file,
                       const base::FilePath& new_file) {
   BufferedFileReader old_buffer(old_file, "'old' input");
   BufferedFileReader patch_buffer(patch_file, "'patch' input");

   courgette::SourceStream old_stream;
   courgette::SourceStream patch_stream;
   old_stream.Init(old_buffer.data(), old_buffer.length());
   patch_stream.Init(patch_buffer.data(), patch_buffer.length());

   courgette::SinkStream new_stream;
   bsdiff::BSDiffStatus status =
       bsdiff::ApplyBinaryPatch(&old_stream, &patch_stream, &new_stream);

   if (status != bsdiff::OK)
     Problem("-applybsdiff failed.");

   WriteSinkToFile(&new_stream, new_file);
 }

 }  // namespace

 int main(int argc, const char* argv[]) {
   base::AtExitManager at_exit_manager;
   base::CommandLine::Init(argc, argv);
   const base::CommandLine& command_line =
       *base::CommandLine::ForCurrentProcess();

   logging::LoggingSettings settings;
   if (command_line.HasSwitch("nologfile")) {
     settings.logging_dest = logging::LOG_TO_SYSTEM_DEBUG_LOG;
   } else {
     settings.logging_dest = logging::LOG_TO_ALL;
     settings.log_file = FILE_PATH_LITERAL("courgette.log");
   }
   (void)logging::InitLogging(settings);
   logging::SetMinLogLevel(logging::LOG_VERBOSE);

   bool cmd_sup = command_line.HasSwitch("supported");
   bool cmd_dis = command_line.HasSwitch("dis");
   bool cmd_asm = command_line.HasSwitch("asm");
   bool cmd_disadj = command_line.HasSwitch("disadj");
   bool cmd_make_patch = command_line.HasSwitch("gen");
   bool cmd_apply_patch = command_line.HasSwitch("apply");
   bool cmd_make_bsdiff_patch = command_line.HasSwitch("genbsdiff");
   bool cmd_apply_bsdiff_patch = command_line.HasSwitch("applybsdiff");
   bool cmd_spread_1_adjusted = command_line.HasSwitch("gen1a");
   bool cmd_spread_1_unadjusted = command_line.HasSwitch("gen1u");

   std::vector<base::FilePath> values;
   const base::CommandLine::StringVector& args = command_line.GetArgs();
   for (size_t i = 0; i < args.size(); ++i) {
     values.push_back(base::FilePath(args[i]));
   }

   // '-repeat=N' is for debugging.  Running many iterations can reveal leaks and
   // bugs in cleanup.
   int repeat_count = 1;
   std::string repeat_switch = command_line.GetSwitchValueASCII("repeat");
   if (!repeat_switch.empty())
     if (!base::StringToInt(repeat_switch, &repeat_count))
       repeat_count = 1;

   if (cmd_sup + cmd_dis + cmd_asm + cmd_disadj + cmd_make_patch +
           cmd_apply_patch + cmd_make_bsdiff_patch + cmd_apply_bsdiff_patch +
           cmd_spread_1_adjusted + cmd_spread_1_unadjusted !=
       1) {
     UsageProblem(
         "First argument must be one of:\n"
         "  -supported, -asm, -dis, -disadj, -gen, -apply, -genbsdiff,"
         " -applybsdiff, or -gen1[au].");
   }

   while (repeat_count-- > 0) {
     if (cmd_sup) {
       if (values.size() != 1)
         UsageProblem(kUsageSupported);
       return !Supported(values[0]);
     } else if (cmd_dis) {
       if (values.size() != 2)
         UsageProblem(kUsageDis);
       Disassemble(values[0], values[1]);
     } else if (cmd_asm) {
       if (values.size() != 2)
         UsageProblem(kUsageAsm);
       Assemble(values[0], values[1]);
     } else if (cmd_disadj) {
       if (values.size() != 3)
         UsageProblem(kUsageDisadj);
       DisassembleAndAdjust(values[0], values[1], values[2]);
     } else if (cmd_make_patch) {
       if (values.size() != 3)
         UsageProblem(kUsageGen);
       GenerateEnsemblePatch(values[0], values[1], values[2]);
     } else if (cmd_apply_patch) {
       if (values.size() != 3)
         UsageProblem(kUsageApply);
       ApplyEnsemblePatch(values[0], values[1], values[2]);
     } else if (cmd_make_bsdiff_patch) {
       if (values.size() != 3)
         UsageProblem(kUsageGenbsdiff);
       GenerateBSDiffPatch(values[0], values[1], values[2]);
     } else if (cmd_apply_bsdiff_patch) {
       if (values.size() != 3)
         UsageProblem(kUsageApplybsdiff);
       ApplyBSDiffPatch(values[0], values[1], values[2]);
     } else if (cmd_spread_1_adjusted || cmd_spread_1_unadjusted) {
       if (values.size() != 3)
         UsageProblem(kUsageGen1);
       DisassembleAdjustDiff(values[0], values[1], values[2],
                             cmd_spread_1_adjusted);
     } else {
       UsageProblem("No operation specified");
     }
   }

   return 0;
 }
	// Copyright (c) 2011 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include <stdarg.h>
	#include <stddef.h>
	#include <stdint.h>

	#include <initializer_list>
	#include <memory>
	#include <string>
	#include <vector>

	#include "base/at_exit.h"
	#include "base/command_line.h"
	#include "base/files/file_path.h"
	#include "base/files/file_util.h"
	#include "base/files/memory_mapped_file.h"
	#include "base/logging.h"
	#include "base/macros.h"
	#include "base/strings/string_number_conversions.h"
	#include "base/strings/string_util.h"
	#include "base/strings/utf_string_conversions.h"
	#include "courgette/assembly_program.h"
	#include "courgette/courgette.h"
	#include "courgette/courgette_flow.h"
	#include "courgette/encoded_program.h"
	#include "courgette/program_detector.h"
	#include "courgette/streams.h"
	#include "courgette/third_party/bsdiff/bsdiff.h"

	namespace {

	using courgette::CourgetteFlow;

	const char kUsageGen[] = "-gen <old_in> <new_in> <patch_out>";
	const char kUsageApply[] = "-apply <old_in> <patch_in> <new_out>";
	const char kUsageGenbsdiff[] = "-genbsdiff <old_in> <new_in> <patch_out>";
	const char kUsageApplybsdiff[] = "-applybsdiff <old_in> <patch_in> <new_out>";
	const char kUsageSupported[] = "-supported <exec_file_in>";
	const char kUsageDis[] = "-dis <exec_file_in> <assembly_file_out>";
	const char kUsageAsm[] = "-asm <assembly_file_in> <exec_file_out>";
	const char kUsageDisadj[] = "-disadj <old_in> <new_in> <new_assembly_file_out>";
	const char kUsageGen1[] = "-gen1[au] <old_in> <new_in> <patch_base_out>";

	/****** Utilities to print help and exit ******/

	void PrintHelp() {
	fprintf(stderr, "Main Usage:\n");
	for (auto usage :
	{kUsageGen, kUsageApply, kUsageGenbsdiff, kUsageApplybsdiff}) {
	fprintf(stderr, " courgette %s\n", usage);
	}
	fprintf(stderr, "Diagnosis Usage:\n");
	for (auto usage :
	{kUsageSupported, kUsageDis, kUsageAsm, kUsageDisadj, kUsageGen1}) {
	fprintf(stderr, " courgette %s\n", usage);
	}
	}

	void UsageProblem(const char* message) {
	fprintf(stderr, "%s", message);
	fprintf(stderr, "\n");
	PrintHelp();
	exit(1);
	}

	void Problem(const char* format, ...) {
	va_list args;
	va_start(args, format);
	vfprintf(stderr, format, args);
	fprintf(stderr, "\n");
	va_end(args);
	exit(1);
	}

	/****** BufferedFileReader ******/

	// A file reader that calls Problem() on failure.
	class BufferedFileReader : public courgette::BasicBuffer {
	public:
	BufferedFileReader(const base::FilePath& file_name, const char* kind) {
	if (!buffer_.Initialize(file_name))
	Problem("Can't read %s file.", kind);
	}
	~BufferedFileReader() override = default;

	// courgette::BasicBuffer:
	const uint8_t* data() const override { return buffer_.data(); }
	size_t length() const override { return buffer_.length(); }

	private:
	base::MemoryMappedFile buffer_;

	DISALLOW_COPY_AND_ASSIGN(BufferedFileReader);
	};

	/****** Various helpers ******/

	void WriteSinkToFile(const courgette::SinkStream* sink,
	const base::FilePath& output_file) {
	int count = base::WriteFile(output_file,
	reinterpret_cast<const char*>(sink->Buffer()),
	static_cast<int>(sink->Length()));
	if (count == -1)
	Problem("Can't write output.");
	if (static_cast<size_t>(count) != sink->Length())
	Problem("Incomplete write.");
	}

	bool Supported(const base::FilePath& input_file) {
	bool result = false;

	BufferedFileReader buffer(input_file, "input");

	courgette::ExecutableType type;
	size_t detected_length;

	DetectExecutableType(buffer.data(), buffer.length(), &type, &detected_length);

	// If the detection fails, we just fall back on UNKNOWN
	std::string format = "Unsupported";

	switch (type) {
	case courgette::EXE_UNKNOWN:
	break;

	case courgette::EXE_WIN_32_X86:
	format = "Windows 32 PE";
	result = true;
	break;

	case courgette::EXE_ELF_32_X86:
	format = "ELF 32 X86";
	result = true;
	break;

	case courgette::EXE_ELF_32_ARM:
	format = "ELF 32 ARM";
	result = true;
	break;

	case courgette::EXE_WIN_32_X64:
	format = "Windows 64 PE";
	result = true;
	break;
	}

	printf("%s Executable\n", format.c_str());
	return result;
	}

	void Disassemble(const base::FilePath& input_file,
	const base::FilePath& output_file) {
	CourgetteFlow flow;
	BufferedFileReader input_buffer(input_file, flow.name(flow.ONLY));
	flow.ReadDisassemblerFromBuffer(flow.ONLY, input_buffer);
	flow.CreateAssemblyProgramFromDisassembler(flow.ONLY, false);
	flow.CreateEncodedProgramFromDisassemblerAndAssemblyProgram(flow.ONLY);
	flow.DestroyDisassembler(flow.ONLY);
	flow.DestroyAssemblyProgram(flow.ONLY);
	flow.WriteSinkStreamSetFromEncodedProgram(flow.ONLY);
	flow.DestroyEncodedProgram(flow.ONLY);
	courgette::SinkStream sink;
	flow.WriteSinkStreamFromSinkStreamSet(flow.ONLY, &sink);
	if (flow.failed())
	Problem(flow.message().c_str());

	WriteSinkToFile(&sink, output_file);
	}

	void DisassembleAndAdjust(const base::FilePath& old_file,
	const base::FilePath& new_file,
	const base::FilePath& output_file) {
	// Flow graph and process sequence (DA = Disassembler, AP = AssemblyProgram,
	// EP = EncodedProgram, Adj = Adjusted):
	// [1 Old DA] --> [2 Old AP] [4 New AP] <-- [3 New DA]
	// \| \| \|
	// \| v (move) v
	// +---> [5 Adj New AP] --> [6 New EP]
	// (7 Write)
	CourgetteFlow flow;
	BufferedFileReader old_buffer(old_file, flow.name(flow.OLD));
	BufferedFileReader new_buffer(new_file, flow.name(flow.NEW));
	flow.ReadDisassemblerFromBuffer(flow.OLD, old_buffer); // 1
	flow.CreateAssemblyProgramFromDisassembler(flow.OLD, true); // 2
	flow.DestroyDisassembler(flow.OLD);
	flow.ReadDisassemblerFromBuffer(flow.NEW, new_buffer); // 3
	flow.CreateAssemblyProgramFromDisassembler(flow.NEW, true); // 4
	flow.AdjustNewAssemblyProgramToMatchOld(); // 5
	flow.DestroyAssemblyProgram(flow.OLD);
	flow.CreateEncodedProgramFromDisassemblerAndAssemblyProgram(flow.NEW); // 6
	flow.DestroyAssemblyProgram(flow.NEW);
	flow.DestroyDisassembler(flow.NEW);
	flow.WriteSinkStreamSetFromEncodedProgram(flow.NEW); // 7
	flow.DestroyEncodedProgram(flow.NEW);
	courgette::SinkStream sink;
	flow.WriteSinkStreamFromSinkStreamSet(flow.NEW, &sink);
	if (flow.failed())
	Problem(flow.message().c_str());

	WriteSinkToFile(&sink, output_file);
	}

	// Diffs two executable files, write a set of files for the diff, one file per
	// stream of the EncodedProgram format. Each file is the bsdiff between the
	// original file's stream and the new file's stream. This is completely
	// uninteresting to users, but it is handy for seeing how much each which
	// streams are contributing to the final file size. Adjustment is optional.
	void DisassembleAdjustDiff(const base::FilePath& old_file,
	const base::FilePath& new_file,
	const base::FilePath& output_file_root,
	bool adjust) {
	// Same as PatchGeneratorX86_32::Transform(), except Adjust is optional, and
	// \|flow\|'s internal SinkStreamSet get used.
	// Flow graph and process sequence (DA = Disassembler, AP = AssemblyProgram,
	// EP = EncodedProgram, Adj = Adjusted):
	// [1 Old DA] --> [2 Old AP] [6 New AP] <-- [5 New DA]
	// \| \| \| \| \|
	// v \| \| v (move) v
	// [3 Old EP] <-----+ +->[7 Adj New AP] --> [8 New EP]
	// (4 Write) (9 Write)
	CourgetteFlow flow;
	BufferedFileReader old_buffer(old_file, flow.name(flow.OLD));
	BufferedFileReader new_buffer(new_file, flow.name(flow.NEW));
	flow.ReadDisassemblerFromBuffer(flow.OLD, old_buffer); // 1
	flow.CreateAssemblyProgramFromDisassembler(flow.OLD, adjust); // 2
	flow.CreateEncodedProgramFromDisassemblerAndAssemblyProgram(flow.OLD); // 3
	flow.DestroyDisassembler(flow.OLD);
	flow.WriteSinkStreamSetFromEncodedProgram(flow.OLD); // 4
	flow.DestroyEncodedProgram(flow.OLD);
	flow.ReadDisassemblerFromBuffer(flow.NEW, new_buffer); // 5
	flow.CreateAssemblyProgramFromDisassembler(flow.NEW, adjust); // 6
	if (adjust)
	flow.AdjustNewAssemblyProgramToMatchOld(); // 7, optional
	flow.DestroyAssemblyProgram(flow.OLD);
	flow.CreateEncodedProgramFromDisassemblerAndAssemblyProgram(flow.NEW); // 8
	flow.DestroyAssemblyProgram(flow.NEW);
	flow.DestroyDisassembler(flow.NEW);
	flow.WriteSinkStreamSetFromEncodedProgram(flow.NEW); // 9
	flow.DestroyEncodedProgram(flow.NEW);
	if (flow.failed())
	Problem(flow.message().c_str());

	courgette::SinkStream empty_sink;
	for (int i = 0;; ++i) {
	courgette::SinkStream* old_stream = flow.data(flow.OLD)->sinks.stream(i);
	courgette::SinkStream* new_stream = flow.data(flow.NEW)->sinks.stream(i);
	if (old_stream == NULL && new_stream == NULL)
	break;

	courgette::SourceStream old_source;
	courgette::SourceStream new_source;
	old_source.Init(old_stream ? *old_stream : empty_sink);
	new_source.Init(new_stream ? *new_stream : empty_sink);
	courgette::SinkStream patch_stream;
	bsdiff::BSDiffStatus status =
	bsdiff::CreateBinaryPatch(&old_source, &new_source, &patch_stream);
	if (status != bsdiff::OK)
	Problem("-xxx failed.");

	std::string append = std::string("-") + base::IntToString(i);

	WriteSinkToFile(&patch_stream,
	output_file_root.InsertBeforeExtensionASCII(append));
	}
	}

	void Assemble(const base::FilePath& input_file,
	const base::FilePath& output_file) {
	CourgetteFlow flow;
	BufferedFileReader input_buffer(input_file, flow.name(flow.ONLY));
	flow.ReadSourceStreamSetFromBuffer(flow.ONLY, input_buffer);
	flow.ReadEncodedProgramFromSourceStreamSet(flow.ONLY);
	courgette::SinkStream sink;
	flow.WriteExecutableFromEncodedProgram(flow.ONLY, &sink);
	if (flow.failed())
	Problem(flow.message().c_str());

	WriteSinkToFile(&sink, output_file);
	}

	void GenerateEnsemblePatch(const base::FilePath& old_file,
	const base::FilePath& new_file,
	const base::FilePath& patch_file) {
	BufferedFileReader old_buffer(old_file, "'old' input");
	BufferedFileReader new_buffer(new_file, "'new' input");

	courgette::SourceStream old_stream;
	courgette::SourceStream new_stream;
	old_stream.Init(old_buffer.data(), old_buffer.length());
	new_stream.Init(new_buffer.data(), new_buffer.length());

	courgette::SinkStream patch_stream;
	courgette::Status status =
	courgette::GenerateEnsemblePatch(&old_stream, &new_stream, &patch_stream);

	if (status != courgette::C_OK)
	Problem("-gen failed.");

	WriteSinkToFile(&patch_stream, patch_file);
	}

	void ApplyEnsemblePatch(const base::FilePath& old_file,
	const base::FilePath& patch_file,
	const base::FilePath& new_file) {
	// We do things a little differently here in order to call the same Courgette
	// entry point as the installer. That entry point point takes file names and
	// returns an status code but does not output any diagnostics.

	courgette::Status status = courgette::ApplyEnsemblePatch(
	old_file.value().c_str(), patch_file.value().c_str(),
	new_file.value().c_str());

	if (status == courgette::C_OK)
	return;

	// Diagnose the error.
	switch (status) {
	case courgette::C_BAD_ENSEMBLE_MAGIC:
	Problem("Not a courgette patch");
	break;

	case courgette::C_BAD_ENSEMBLE_VERSION:
	Problem("Wrong version patch");
	break;

	case courgette::C_BAD_ENSEMBLE_HEADER:
	Problem("Corrupt patch");
	break;

	case courgette::C_DISASSEMBLY_FAILED:
	Problem("Disassembly failed (could be because of memory issues)");
	break;

	case courgette::C_STREAM_ERROR:
	Problem("Stream error (likely out of memory or disk space)");
	break;

	default:
	break;
	}

	// If we failed due to a missing input file, this will print the message.
	{ BufferedFileReader old_buffer(old_file, "'old' input"); }
	{ BufferedFileReader patch_buffer(patch_file, "'patch' input"); }

	// Non-input related errors:
	if (status == courgette::C_WRITE_OPEN_ERROR)
	Problem("Can't open output");
	if (status == courgette::C_WRITE_ERROR)
	Problem("Can't write output");

	Problem("-apply failed.");
	}

	void GenerateBSDiffPatch(const base::FilePath& old_file,
	const base::FilePath& new_file,
	const base::FilePath& patch_file) {
	BufferedFileReader old_buffer(old_file, "'old' input");
	BufferedFileReader new_buffer(new_file, "'new' input");

	courgette::SourceStream old_stream;
	courgette::SourceStream new_stream;
	old_stream.Init(old_buffer.data(), old_buffer.length());
	new_stream.Init(new_buffer.data(), new_buffer.length());

	courgette::SinkStream patch_stream;
	bsdiff::BSDiffStatus status =
	bsdiff::CreateBinaryPatch(&old_stream, &new_stream, &patch_stream);

	if (status != bsdiff::OK)
	Problem("-genbsdiff failed.");

	WriteSinkToFile(&patch_stream, patch_file);
	}

	void ApplyBSDiffPatch(const base::FilePath& old_file,
	const base::FilePath& patch_file,
	const base::FilePath& new_file) {
	BufferedFileReader old_buffer(old_file, "'old' input");
	BufferedFileReader patch_buffer(patch_file, "'patch' input");

	courgette::SourceStream old_stream;
	courgette::SourceStream patch_stream;
	old_stream.Init(old_buffer.data(), old_buffer.length());
	patch_stream.Init(patch_buffer.data(), patch_buffer.length());

	courgette::SinkStream new_stream;
	bsdiff::BSDiffStatus status =
	bsdiff::ApplyBinaryPatch(&old_stream, &patch_stream, &new_stream);

	if (status != bsdiff::OK)
	Problem("-applybsdiff failed.");

	WriteSinkToFile(&new_stream, new_file);
	}

	} // namespace

	int main(int argc, const char* argv[]) {
	base::AtExitManager at_exit_manager;
	base::CommandLine::Init(argc, argv);
	const base::CommandLine& command_line =
	*base::CommandLine::ForCurrentProcess();

	logging::LoggingSettings settings;
	if (command_line.HasSwitch("nologfile")) {
	settings.logging_dest = logging::LOG_TO_SYSTEM_DEBUG_LOG;
	} else {
	settings.logging_dest = logging::LOG_TO_ALL;
	settings.log_file = FILE_PATH_LITERAL("courgette.log");
	}
	(void)logging::InitLogging(settings);
	logging::SetMinLogLevel(logging::LOG_VERBOSE);

	bool cmd_sup = command_line.HasSwitch("supported");
	bool cmd_dis = command_line.HasSwitch("dis");
	bool cmd_asm = command_line.HasSwitch("asm");
	bool cmd_disadj = command_line.HasSwitch("disadj");
	bool cmd_make_patch = command_line.HasSwitch("gen");
	bool cmd_apply_patch = command_line.HasSwitch("apply");
	bool cmd_make_bsdiff_patch = command_line.HasSwitch("genbsdiff");
	bool cmd_apply_bsdiff_patch = command_line.HasSwitch("applybsdiff");
	bool cmd_spread_1_adjusted = command_line.HasSwitch("gen1a");
	bool cmd_spread_1_unadjusted = command_line.HasSwitch("gen1u");

	std::vector<base::FilePath> values;
	const base::CommandLine::StringVector& args = command_line.GetArgs();
	for (size_t i = 0; i < args.size(); ++i) {
	values.push_back(base::FilePath(args[i]));
	}

	// '-repeat=N' is for debugging. Running many iterations can reveal leaks and
	// bugs in cleanup.
	int repeat_count = 1;
	std::string repeat_switch = command_line.GetSwitchValueASCII("repeat");
	if (!repeat_switch.empty())
	if (!base::StringToInt(repeat_switch, &repeat_count))
	repeat_count = 1;

	if (cmd_sup + cmd_dis + cmd_asm + cmd_disadj + cmd_make_patch +
	cmd_apply_patch + cmd_make_bsdiff_patch + cmd_apply_bsdiff_patch +
	cmd_spread_1_adjusted + cmd_spread_1_unadjusted !=
	1) {
	UsageProblem(
	"First argument must be one of:\n"
	" -supported, -asm, -dis, -disadj, -gen, -apply, -genbsdiff,"
	" -applybsdiff, or -gen1[au].");
	}

	while (repeat_count-- > 0) {
	if (cmd_sup) {
	if (values.size() != 1)
	UsageProblem(kUsageSupported);
	return !Supported(values[0]);
	} else if (cmd_dis) {
	if (values.size() != 2)
	UsageProblem(kUsageDis);
	Disassemble(values[0], values[1]);
	} else if (cmd_asm) {
	if (values.size() != 2)
	UsageProblem(kUsageAsm);
	Assemble(values[0], values[1]);
	} else if (cmd_disadj) {
	if (values.size() != 3)
	UsageProblem(kUsageDisadj);
	DisassembleAndAdjust(values[0], values[1], values[2]);
	} else if (cmd_make_patch) {
	if (values.size() != 3)
	UsageProblem(kUsageGen);
	GenerateEnsemblePatch(values[0], values[1], values[2]);
	} else if (cmd_apply_patch) {
	if (values.size() != 3)
	UsageProblem(kUsageApply);
	ApplyEnsemblePatch(values[0], values[1], values[2]);
	} else if (cmd_make_bsdiff_patch) {
	if (values.size() != 3)
	UsageProblem(kUsageGenbsdiff);
	GenerateBSDiffPatch(values[0], values[1], values[2]);
	} else if (cmd_apply_bsdiff_patch) {
	if (values.size() != 3)
	UsageProblem(kUsageApplybsdiff);
	ApplyBSDiffPatch(values[0], values[1], values[2]);
	} else if (cmd_spread_1_adjusted \|\| cmd_spread_1_unadjusted) {
	if (values.size() != 3)
	UsageProblem(kUsageGen1);
	DisassembleAdjustDiff(values[0], values[1], values[2],
	cmd_spread_1_adjusted);
	} else {
	UsageProblem("No operation specified");
	}
	}

	return 0;
	}